EP1271888B1 - Method for transferring of Internet protocol based communication data - Google Patents

Description

The invention relates to a method for internet protocol-based Transmission, in particular real-time transmission of Communication data, such as Voice, video and / or multimedia data.

In contemporary communication systems is used for data transmission between data processing facilities mainly the so-called Internet Protocol - abbreviated IP - used. In the Internet Protocol, data to be transmitted becomes data packets divided, each with a transmission goal identifying destination address, regardless be transmitted from one another to the transmission destination. Such data packets are often referred to as Internet Protocol Datagrams or IP Datagrams.

Because of its worldwide distribution as well as very much low data transmission costs win this Internet Protocol increasingly also for a real-time transmission of communication data in importance. Since that Internet protocol, however, not with respect to real-time applications it has some designed for real-time applications adverse properties. For example, because the internet protocol datagrams are independent of each other the transmission times of the Internet protocol datagrams vary greatly. In addition, kick due to asynchronous transmission of Internet Protocol datagrams especially at high transmission load packet collisions on delaying or discarding all Internet Protocol Datagrams.

The document WO 01/35587 discloses a packet switching method, where the data packets are time aligned, so that the switcher a communication network, the time-aligned data packets based their relative position within a given timeframe structure.

To compensate for transmission time fluctuations are at Internet Protocol datagrams arriving to a receiver usually cached in a buffer memory, from which they are read out at constant intervals. However, the buffering of Internet Protocol datagrams requires another delay, which in many real-time applications is not tolerable.

It is an object of the present invention a method for internet protocol based transmission, in particular Specify real-time transmission of communication data with the transmission time fluctuations can be avoided.

This task is solved by a procedure with the Features of claim 1.

In the context of the method according to the invention, a communication data stream, such as. a voice, video and / or Multimedia data stream, within Internet Protocol datagrams transmitted over a communication network. The transfer is based on a timestamp, to a sender of the internet protocol datagrams is transmitted. The transmission of the time stamp, the for example as a time pulse or as time information can be configured, preferably in regular Repeated intervals. Based on the received timestamp are timed by the sender at this timestamp aligned time intervals or groups of time intervals reserved for transmission of internet protocol datagrams. The Internet Protocol datagrams are each one of Time intervals assigned and within each associated time interval by the sender according to Internet Protocol transfer.

The sender of the internet protocol datagrams may e.g. an IP phone, IP video, a personal computer or an IP application program be.

The individual time intervals or groups of time intervals can in a sense be considered as different transmission channels be understood. By the explicit assignment of to transmitted Internet Protocol datagrams at airtime intervals can the number of datagram collisions in the communication network be reduced considerably, which Transmission time variations of Internet Protocol datagrams be significantly reduced. This allows smaller ones Datagram cache or often even completely to refrain from such buffers, resulting in again the transmission time of the internet protocol datagrams significantly shortened.

Another advantage of the method according to the invention consists in that it can be done without major effort in existing internet protocol communication networks is implementable. To the Receiving the means of the method according to the invention sent internet protocol datagrams are not any modifications on a traditional receiver of Internet Protocol datagrams required. The invention Method can thus be used backward compatible.

Furthermore, a load control of the traffic is on easy to implement.

Advantageous embodiments and further developments of Invention are given in the dependent claims.

According to an advantageous embodiment of the invention can the timestamp by a central timestamp source, such as For example, a router device or a server over which Communication network are transmitted to the transmitter. The Transmission of the timestamp may preferably be on the physical Layer (layer 1) of the OSI reference model. Advantageously, the timestamp can be connected to several or all Sender of Internet Protocol datagrams in the Communication network or in one of its sub-areas of be transmitted to a central time stamp source. The one Timestamp receiving stations can be timed by synchronized with each other, whereby the in the respective stations according to the invention to be reserved time intervals be precisely aligned against each other in time. The transmission of the timestamp allows more elaborate Protocols, e.g. the so-called NTP protocol (NTP: Network Time Protocol), to synchronize the transmitter to without.

According to a further advantageous embodiment of the Invention, the time intervals in regular, preferably Reserved almost constant time intervals.

According to an advantageous embodiment of the invention can be determined by the transmitter, which of the time intervals not from other transmitters in the communication network for data transmission be used. The internet protocol datagrams to be transmitted then only these will not be otherwise assigned time intervals and within this Transfer time intervals. In this way, collisions can occur Internet Protocol datagrams with broadcasters too transmitted Internet Protocol datagrams effectively avoided become. In particular, it can be avoided that in continuing Network devices of the communication network, such as For example, router devices or so-called hubs, themselves temporally overlapping internet protocol datagrams arrive for their forwarding only a single line is available.

The determination of those time intervals not from other transmitters in the communication network for data transmission can be used, for example, based on a reception Allocation information is provided by the broadcasters reservable time intervals are assigned. alternative For this purpose, the transmitter, the other channels to unused Interrogate time intervals or split the time intervals Negotiate with the other broadcasters. After another Variant, the transmitter can also datagram traffic in the communication network monitor and thus free, determine reservable time intervals.

According to an advantageous embodiment of the invention other internet protocol datagrams - especially for Transport of non-real-time data - outside the reserved Time intervals asynchronous, that means without specification of one exact transmission time. The entire available Data transfer time is thus determined by the reservation of the Time intervals, so to speak, in a reserved, synchronous part for transmitting the communication data stream and an asynchronous part outside the reserved one Time intervals for the transmission of non-real-time data, for Example control or signaling data, divided.

Preferably, reserved and non-reserved Alternate time intervals at predetermined intervals.

The proportion of time intervals to be reserved on the total available data transfer time may be as required, for example, depending on the proportion of real-time data in the whole Data transfer volume can be varied.

In particular, with the timestamp one the proportion of reserving time intervals predetermining time allocation information be transmitted to the transmitter.

According to a further advantageous embodiment of the invention can be used as part of an initialization, e.g. the transmitter, one Receiver and / or another network device of the Communication network, the proportion of reserved Time intervals are increased from zero. This means that initially no time intervals reserved and thus all data to be transmitted first be transmitted asynchronously. In this phase, the Data transmission completely on the conventional, asynchronous internet protocol. An inventive transmitter of Internet Protocol datagrams can thus first determine whether the inventive method in Communication network is supported, and if so, begin to reserve time intervals. If the transmitter On the other hand, no support recognizes, for example, because no Timestamp is received, the sender can access a Do not reserve time intervals. This is one inventive transmitter also backward compatible in conventional communication networks can be integrated.

According to a further advantageous development of the invention can by the sender another, at the received Timestamp timed time interval or one another sequence of time intervals for another communication protocol reserved. As another communication protocol may preferably be a simpler protocol be implemented, with less tax and administrative data to be transmitted with the user data as when Internet Protocol. In particular, in the other Communication protocol address, control or channel information by the relative position of a data packet in the be expressed further time interval.

An embodiment of the invention will be described below explained in detail the drawing.

Fig 1 ein internetprotokollbasiertes Kommunikationsnetz zur Echtzeitübertragung von Kommunikationsdatenströmen,

Fig 2 eine Zeitrahmenstruktur für eine Übertragung von Internetprotokoll-Datagrammen und

Fig 3a, 3b und 3c jeweils die zeitliche Ausrichtung von Internetprotokoll-Datagrammen bezüglich der Zeitrahmenstruktur.

In each case show in a schematic representation:

1 shows an internet protocol-based communication network for the real-time transmission of communication data streams,

2 shows a time frame structure for a transmission of Internet Protocol datagrams and

3a, 3b and 3c respectively show the time alignment of Internet Protocol datagrams with respect to the time frame structure.

1 shows schematically an Internet Protocol-based communication network comprising a local area network LAN1, a local area network LAN2 and a wide area network WAN, such as the Internet, as subnetworks. The subnetworks LAN1, LAN2 and WAN are coupled to one another via a router device ROU, via which Internet protocol datagrams, referred to below as IP datagrams, are switched between the individual subnetworks LAN1, LAN2 and WAN.

Furthermore, to the local area network LAN1 is an internet protocol based Communication terminal IPT1 and to the local network LAN2 an internet protocol based communication terminal IPT2 docked. The communication terminals IPT1 and IPT2 For example, IP phones, IP videophones, Personal computer or any other transmitter of communication data be designed.

In the context of the inventive method is of the Router device ROU a time stamp ZM via the local network LAN1 to the communication terminal IPT1 and via the local network LAN2 to the communication terminal IPT2 transmitted. The Timestamp ZM can, for example, by a time pulse or be a time specification realized. Preferably, the Timestamp ZM on the physical layer, that is Layer 1 of the OSI Reference Model transmitted to a to ensure particularly accurate synchronization. Based on Timestamp ZM could be the communication terminals IPT1 and IPT2 be synchronized to each other by their clock generators (not shown) or real-time clocks (not shown) be aligned in time to the received timestamp ZM. The received time stamp ZM can also be used in addition be used, the time on a display of the communication terminal IPT1 or IPT2. A separate Transmission of time information about a complex Synchronization protocol, such as the NTP protocol (Network Time Protocol), can thus be omitted.

According to an alternative embodiment of the invention, the Timestamp ZM instead of the router device ROU also from another network device, e.g. a so-called Hub, a server, etc., centrally to the attached communication terminals, here IPT1 and IPT2, or any additional network devices to be synchronized be transmitted.

Of the communication terminals IPT1 and IPT2 is in the each embodiment, a communication data stream in real time in the wide area network WAN transfer. In addition to the respective communication data stream, for example, voice, video and / or multimedia data may be from the communication terminals IPT1 and IPT2 also non-real-time data, such as Signaling, control and / or file data into the Wide area network WAN transferred.

The communication data stream originating from the communication terminal IPT1 gets within with a destination address assigned IP datagrams D1, which are transmitted via the local Network LAN1 and the router device ROU in the wide area network WAN to be transmitted. Accordingly, those of the Communication terminal IPT1 outgoing non-real-time data within each IP address datagram provided with a destination address S1 via the local area network LAN1 and the router device ROU transmitted to the wide area network WAN. Analogous These are the outgoing from the communication terminal IPT2 Communication data stream within IP datagrams D2 and IPT2 non-real-time data within IP datagrams S2 via the local network LAN2 and the router device ROU transmitted to the wide area network WAN.

The transmission of real-time communication data containing IP datagrams D1, D2 is based on a according to the invention given timeframe structure. Due to the predetermined Timeframe structure are IP datagrams containing real-time data no longer asynchronous as in traditional IP based Communication networks, but within specific reserved time intervals, that is, in a sense synchronous, transmitted.

FIG. 2 shows an example of such a time frame structure in a schematic representation. The beginning of a respective time frame is marked by the receipt of the time mark ZM. Subsequently, reserved time intervals K1, K2, K3 and unreserved time intervals NRZI alternate until a time mark ZM, which initiates the next time frame, is received again. In the present exemplary embodiment, three adjoining time intervals K1, K2 and K3, which are reserved for IP datagrams containing real-time data, initially follow the time mark ZM. Immediately thereafter follows an unreserved time interval NRZI. The time interval group consisting of three reserved time intervals K1, K2 and K3 and an unreserved time interval NRZI then repeats at regular time intervals until the reception of the next time mark ZM. An advantageous guideline value for the duration of a time interval group for many applications is approximately 20 ms. Preferably, the boundary between reserved and unreserved time intervals is variable. For continuous synchronization of the time frames of the communication terminals IPT1 and IPT2, the time marks ZM are transmitted at regular, preferably almost constant, time intervals of, for example, 1 s.

Preferably, the reserved time intervals K1, K2, K3 according to their relative position in their respective time interval group assigned to different transmission channels. Thus, they form a respective time interval group Time intervals K1 a first transmission channel, the second position located time intervals K2 a second Transmission channel and the third located Time intervals K3 a third transmission channel. The individual transmission channels can to some extent as Time division multiplex channels are considered, the invention in embedded the asynchronous concept of Internet Protocol are.

The following are the transmission channels for the sake of Clarity each with the same reference number as the respectively assigned time intervals K1, K2 and K3 designated.

For real-time transmission of a communication data stream be for this one or more transmission channels K1, K2 or K3 reserved. This is done with each IP datagram of the Communication data stream in each case a time interval of or allocated exclusively to the reserved transmission channels, within which the respective IP datagram is transmitted. To an IP datagram containing communication data exactly within the time interval assigned to it, If necessary, this IP datagram is up to the beginning of the to delay allocated time interval. The relative Send time of an IP datagram within one Time interval group can - if the reserved Time intervals K1, K2, K3 have the same length - by Multiplication of the length of a time interval K1, K2, K3 with a zeroing transmission channel numbering be determined.

3a shows a schematic representation of the time alignment of the IP datagrams D1 and S1 originating from the communication terminal IPT1 with respect to the predetermined time frame structure. For the transmission of the real-time data containing IP datagrams D1, the transmission channels K1 and K3 are reserved, in which the IP datagrams D1 are transmitted to the router device ROU. For the non-time data-containing IP datagram S1 no specific transmission channel is reserved, so that the IP datagram S1 is transmitted asynchronously to the router device ROU within the unreserved time interval NRZI.

Analogously, the time alignment of the IP datagrams D2 and S2 originating from the communication terminal IPT2 is schematically illustrated in FIG. 3b with respect to the predetermined time frame structure. For the real-time data containing IP datagrams D2 of the second transmission channel, that is, the time intervals K2 reserved for transmission. By contrast, no specific time interval is reserved for the IP datagrams S2 containing the non-real-time data, so that the IP datagrams S2 are transmitted to the router device ROU within the unreserved time intervals NRZI. As indicated in FIG. 3b, the IP datagrams S2 are transmitted asynchronously within the unreserved time intervals NRZI, that is to say without any special time alignment relative to the time interval boundaries.

Due to the assignment of the IP datagrams D1 and D2 to the non-overlapping time intervals K1, K3 and K2 Prevents ROU from overriding the router to forward the same line to the wide area network WAN IP datagrams D1 and D2 collide with each other in time. A temporal collision of at the router device ROU Incoming IP datagrams would result in at least discarded one of these IP datagrams or at least until Freeing up the secondary line would be delayed. This However, this would lead to difficult to predict runtime fluctuations which negatively affect the real-time behavior of the Transmission.

The assignment of the communication data streams to the transmission channels K1, K2, K3 is done in such a way that only ever one of the communication terminals IPT1 and IPT2 on one transmit respective transmission channel K1, K2 and K3. A corresponding temporary reservation of a transmission channel K1, K2, K3 for a respective communication terminal, here IPT1 or IPT2, for example, by submitting a Reservation or allocation information to the communication terminals IPT1 and IPT2 take place. The reservation or Allocation information may preferably be provided by a central Network device are transmitted. Alternatively can the communication terminals IPT1 and IPT2 with each other - by exchanging relevant messages - negotiate which transmission channels or time intervals of which communication terminal, here IPT1 or IPT2, be reserved or reserved. After another Embodiment of the method may be Communication terminal IPT1 or IPT2 a free Transmission channel through observation of network traffic determine yourself.

Due to the assignment of IP datagrams containing real-time data D1 and D2 at non-overlapping time intervals K1, K2, K3 will be IP datagram collisions at least for Real-time data streams avoided. The non-exclusive reserved time intervals NRZI asynchronously transmitted IP datagrams, here S1 and S2, however, can in the Router device ROU quite collide.

3c shows a schematic representation of the time alignment of the IP datagrams D1, D2, S1 and S2 forwarded by the router device ROU to the wide area network WAN with respect to the predetermined time frame structure. Since the IP datagrams D1, D2 have arrived in reserved, non-overlapping time intervals at the router device ROU, this can forward the IP datagrams D1 and D2 in the order and time alignment of their arrival in the wide area network WAN. As a rule, the IP datagrams D1 and D2 can be forwarded to the wide area network WAN with a small but almost constant delay and, in particular, without significant collision-related transit time fluctuations in adjoining time intervals K1, K2, K3.

According to a variant of the method, the router device ROU - or any other network device - over certain Transmission channels incoming IP datagrams to their Forwarding to other transmission channels, i. to others implement reserved time intervals. The implementation is Preferably to be carried out so that the occurring Delays for each of the transferred transmission channels each have a nearly constant channel specific value.

In contrast to the IP datagrams D1 and D2, in present embodiment asynchronously transmitted IP datagram S1 almost simultaneously in one of the asynchronous transmitted IP datagrams S2 at the router device ROU one. For forwarding to the wide area network WAN is therefore one of these IP datagrams, here S1, through the Router device ROU to the next transmission opportunity too delay. In the present embodiment, the IP datagram S1 only in the unreserved time interval NRZI the next time interval group. Since that IP Datagram S1 contains non-real-time data is the However, occurring delay is generally tolerable.

The division of the time frame into reserved time intervals K1, K2, K3 for the synchronous transmission of real-time data and non-reserved time intervals NRZI for the asynchronous transmission of non-real-time data can advantageously be adapted to the respective current data transmission volume of real-time or non-real-time data. For example,
if the transmission volume of the real-time data outweighs, the proportion of the time intervals to be reserved in the total available data transmission time to be increased accordingly. Similarly, with a small proportion of real-time data to be transmitted, the proportion of time intervals to be reserved can be correspondingly reduced. To adapt the proportion of the time intervals to be reserved, for example, their number or their length can be varied. The proportion of the time intervals to be reserved can be determined, for example, on the basis of a time distribution information to be transmitted with the time mark ZM. In extreme cases, if only non-real-time data is to be transmitted, the entire available data transfer time can be released for conventional, asynchronous transmission of IP datagrams.

The reservation and assignment or allocation of the Send time intervals for IP datagrams may be preferred as a new so-called quality of service function (QoS function; QoS: Quality of Service) implemented in the communication network become.

Due to the reservation of time intervals for transmission of real-time data is in the inventive method in Difference to traditional IP based Transmission method a respective transmission time of IP datagrams no longer arbitrary, but on predetermined time intervals, here K1, K2, K3 or NRZI, limited. In a receiver of the invention On the other hand, sent IP datagrams are not implementation changes compared to the conventional internet protocol required. Thus, communication devices, here IPT1 and IPT2, the IP datagrams according to the invention Send methods, even in conventional, asynchronous IP-based Communication networks are operated.

The variable distribution of the total available data transfer time in reserved and not reserved Time intervals, allows an easy to log on adapting different network environments Initialization of the method according to the invention: here is at the beginning of the initialization by the after according to the invention operating transmitter initially no Time interval for the transmission of real-time data reserved, so first the entire Data transfer time for the conventional, asynchronous Transmission is available. Meanwhile try the Sender, here IPT1 and IPT2 to receive a time stamp ZM. If no such timestamp is received, none Reservation of time intervals for the transmission of Real-time data instead. If, on the other hand, such a time mark ZM received by a sender, this sets a time frame temporally at the received timestamp ZM and reserved predeterminable time intervals of the time frame according to the invention for a transmission of real-time data.

Claims (11)

1. Method for transmitting a communications data stream using Internet protocol datagrams (D1, D2) via a communications network, where

   a) a timestamp (ZM) is transmitted to a transmitter (IPT1, IPT2) of the Internet protocol datagrams (D1, D2),

   b) the transmitter (IPT1, IPT2) reserves time intervals (K1, K2, K3) whose timing is geared to the received timestamp (ZM) for the purpose of transmitting the Internet protocol datagrams (D1, D2) which transport the communications data stream,

   c) the transmitter (IPT1, IPT2) ascertains which of the time intervals (K1, K2, K3) are not being used for data transmission by another transmitter in the communications network,

   d) the Internet protocol datagrams (D1, D2) are respectively assigned to one of the time intervals (K1, K2, K3) not used elsewhere, and

   e) a respective Internet protocol datagram (D1, D2) within the time interval (K1, K2, K3) associated therewith is transmitted by the transmitter (IPT1, IPT2) in line with the Internet protocol.
2. Method according to Claim 1,
   characterized in that the timestamp (ZM) is transmitted to the transmitter (IPT1, IPT2) via the communications network by a central timestamp source (ROU).
3. Method according to one of the preceding claims,
   characterized in that the time intervals (K1, K2, K3) are derived from a clock generator or a real-time clock in the transmitter (IPT1, IPT2), the clock generator or the real-time clock being synchronized by means of the received timestamp (ZM).
4. Method according to one of the preceding claims,
   characterized in that the time intervals (K1, K2, K3) are reserved at regular time periods.
5. Method according to one of the preceding claims,
   characterized in that the transmitter (IPT1, IPT2) ascertains which of the time intervals (K1, K2, K3) are not being used for data transmission by another transmitter in the communications network, and
   in that the Internet protocol datagrams (D1, D2) are assigned only to these time intervals not used elsewhere and are transmitted within these time intervals.
6. Method according to one of the preceding claims,
   characterized in that further Internet protocol datagrams (S1, S2) outside the reserved time intervals (K1, K2, K3) are transmitted asynchronously.
7. Method according to one of the preceding claims,
   characterized in that the share of the time intervals (K1, K2, K3) to be reserved in the total available data transmission time is varied according to requirements.
8. Method according to Claim 7,
   characterized in that a time split information item prescribing the share of the time intervals (K1, K2, K3) to be reserved is transmitted to the transmitter (IPT1, IPT2) with the timestamp (ZM).
9. Method according to Claim 7 or 8,
   characterized in that initialization involves increasing the share of the time intervals (K1, K2, K3) to be reserved starting from zero.
10. Method according to one of the preceding claims,
    characterized in that the transmitter (IPT1, IPT2) reserves a further time interval whose timing is geared to the received timestamp (ZM) for a further communications protocol.
11. Method according to one of the preceding claims,
    characterized in that the timestamp (ZM) is transmitted on the physical layer of the OSI reference model.

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